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Introduction

  • A complete analytical solution for the equation of motion in the case of a laminar flow is available, even the advanced theories in the analysis of turbulent flow depend at some point on experimentally derived information. Flow through pipes is usually turbulent in practice. 
     
  • One of the most important items of information that an hydraulic engineer needs is the power required to force fluid at a certain steady rate through a pipe or pipe network system. This information is furnished in practice through some routine solution of pipe flow problems with the help of available empirical and theoretical information. 
     
  • This lecture deals with the typical approaches to the solution of pipe flow problems in practice.

 Concept of Friction Factor in a pipe flow:

  • The friction factor in the case of a pipe flow was already mentioned in lecture 26. 
  • We will elaborate further on friction factor or friction coefficient in this section. 
  • Skin friction coefficient for a fully developed flow through a closed duct is defined as

Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering              (35.1)                       

where, V  is the average velocity of flow given by  V= Q/ A , Q and A are the volume flow rate through the duct and the cross-sectional area of the duct respectively.

From a force balance of a typical fluid element (Fig. 35.1) in course of its flow through a duct of constant cross-sectional area, we can write

Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering                      (35.2)                 

Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering        

where, Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering is the shear stress at the wall and  Δp* is the piezometric pressure drop over a length of and Sare respectively the cross-sectional area and wetted perimeter of the duct. 
Substituting the expression (35.2) in Eq. (35.1), we have,

Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering

where,   Dh = 4 A/S  and is known as the hydraulic diameter 

In case of a circular pipe,  D= D, the diameter of the pipe. The coefficient Cf  defined by Eqs (35.1) or (35.3) is known as Fanning's friction factor .

  • To do away with the factor 1/4 in the Eq. (35.3), Darcy defined a friction factor f (Darcy's friction factor) as

                      Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering        (35.4)                 

  • Comparison of Eqs (35.3) and (35.4) gives

              Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering             (35.5)
  • Equation (35.5) is written in a different fashion for its use in the solution of pipe flow problems in practice as

                   Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering          (35.6a) 

or in terms of head loss (energy loss per unit weight)

                        Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering               (35.6b) 

where, hf  represents the loss of head due to friction over the length L of the pipe.

  • Equation (35.6b) is frequently used in practice to determine h
  • In order to evaluate hf, we require to know the value of f. The value of f can be determined from Moody's Chart.

Variation of Friction Factor

  • In case of a laminar fully developed flow through pipes, the friction factor, f is found from the exact solution of the Navier-Stokes equation as discussed in lecture 26. It is given by
  • f = 64/Re          (35.7)                                                                       
  • In the case of a turbulent flow, friction factor depends on both the Reynolds number and the roughness of pipe surface. 
  • Sir Thomas E. Stanton (1865-1931) first started conducting experiments on a number of pipes of various diameters and materials and with various fluids. Afterwards, a German engineer Nikuradse carried out experiments on flows through pipes in a very wide range of Reynolds number. 
  • A comprehensive documentation of the experimental and theoretical investigations on the laws of friction in pipe flows has been presented in the form of a diagram, as shown in Fig. 35.2, by L.F. Moody to show the variation of friction factor, f with the pertinent governing parameters, namely, the Reynolds number of flow and the relative roughness  Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering of the pipe. This diagram is known as Moody's Chart which is employed till today as the best means for predicting the values of f .

  Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering

Figure 35.2 depicts that

  • The friction factor at a given Reynolds number, in the turbulent region, depends on the relative roughness, defined as the ratio of average roughness to the diameter of the pipe, rather than the absolute roughness. 
  • For moderate degree of roughness, a pipe acts as a smooth pipe up to a value of Re where the curve of f vs Re for the pipe coincides with that of a smooth pipe. This zone is known as the smooth zone of flow 
  • The region where f vs Re curves (Fig. 35.2) become horizontal showing that is independent of Re, is known as the rough zone and the intermediate region between the smooth and rough zone is known as the transition zone
  • The position and extent of all these zones depend on the relative roughness of the pipe. In the smooth zone of flow, the laminar sublayer becomes thick, and hence, it covers appreciably the irregular surface protrusions. Therefore all the curves for smooth flow coincide. 
  • With increasing Reynolds number, the thickness of sublayer decreases and hence the surface bumps protrude through it. The higher is the roughness of the pipe, the lower is the value of Re at which the curve of f vs Re branches off from smooth pipe curve (Fig. 35.2). 
  • In the rough zone of flow, the flow resistance is mainly due to the form drag of those protrusions. The pressure drop in this region is approximately proportional to the square of the average velocity of flow. Thus f becomes independent of Re in this region.

In practice, there are three distinct classes of problems relating to flow through a single pipe line as follows:

  1. The flow rate and pipe diameter are given. One has to determine the loss of head over a given length of pipe and the corresponding power required to maintain the flow over that length. 
  2. The loss of head over a given length of a pipe of known diameter is given. One has to find out the flow rate and the transmission of power accordingly. 
  3. The flow rate through a pipe and the corresponding loss of head over a part of its length are given. One has to find out the diameter of the pipe.

In the first category of problems, the friction factor f is found out explicitly from the given values of flow rate and pipe diameter. Therefore, the loss of head hf and the power required, P can be calculated by the straightforward application of Eq.(35.6b).       

The document Introduction: Applications of Viscous Flows Through Pipes - 1 | Fluid Mechanics for Mechanical Engineering is a part of the Mechanical Engineering Course Fluid Mechanics for Mechanical Engineering.
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FAQs on Introduction: Applications of Viscous Flows Through Pipes - 1 - Fluid Mechanics for Mechanical Engineering

1. What are some common applications of viscous flows through pipes?
Ans. Some common applications of viscous flows through pipes include transportation of fluids such as water, oil, or gas in various industries, cooling and heating systems, chemical processing, and sewage systems.
2. How does viscosity affect the flow of fluids in pipes?
Ans. Viscosity is a measure of a fluid's resistance to flow. In pipes, higher viscosity fluids experience more resistance, resulting in slower flow rates. This can affect the efficiency of transportation systems and may require additional pumping power to maintain desired flow rates.
3. What factors can influence the viscosity of fluids in pipes?
Ans. Several factors can influence the viscosity of fluids in pipes, including temperature, pressure, and the composition of the fluid. Viscosity generally decreases with increasing temperature and can vary significantly depending on the type of fluid being transported.
4. How is pressure drop calculated in viscous flows through pipes?
Ans. Pressure drop in viscous flows through pipes can be calculated using various formulas, such as the Darcy-Weisbach equation or the Hazen-Williams equation. These equations take into account factors such as pipe diameter, fluid velocity, and the roughness of the pipe's inner surface.
5. What are some challenges associated with viscous flows in pipes?
Ans. Some challenges associated with viscous flows in pipes include increased frictional losses, pressure drop, and the potential for pipe clogging due to the accumulation of solid particles or debris. These challenges may require regular maintenance, proper pipe sizing, and the use of appropriate filtration systems.
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